Category:Classical mechanics

Subcategories

This category has the following 15 subcategories, out of 15 total.

Media in category "Classical mechanics"

The following 200 files are in this category, out of 320 total.

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  2 particles constrained cylindrical surface.svg 231 × 327; 31 KB
  
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  2 particles constrained spherical surface.svg 231 × 291; 80 KB
  
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  Uebertragungsfunktion.jpg 6,101 × 3,712; 1.14 MB
  
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  A-Combined-In-Vitro-Imaging-and-Multi-Scale-Modeling-System-for-Studying-the-Role-of-Cell-Matrix-pone.0148254.s002.ogv 8.0 s, 1,284 × 982; 26.57 MB
  
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  A-Combined-In-Vitro-Imaging-and-Multi-Scale-Modeling-System-for-Studying-the-Role-of-Cell-Matrix-pone.0148254.s003.ogv 8.0 s, 1,284 × 982; 23 MB
  
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  A-Combined-In-Vitro-Imaging-and-Multi-Scale-Modeling-System-for-Studying-the-Role-of-Cell-Matrix-pone.0148254.s004.ogv 5.7 s, 1,920 × 1,084; 5.16 MB
  
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  A-Combined-In-Vitro-Imaging-and-Multi-Scale-Modeling-System-for-Studying-the-Role-of-Cell-Matrix-pone.0148254.s005.ogv 5.7 s, 1,920 × 1,084; 1.48 MB
  
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  A-MRI-Compatible-Combined-Mechanical-Loading-and-MR-Elastography-Setup-to-Study-Deformation-Induced-pone.0169864.s003.ogv 2.0 s, 2,000 × 1,630; 1.4 MB
  
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  A-Tubular-Biomaterial-Construct-Exhibiting-a-Negative-Poissons-Ratio-pone.0155681.s001.ogv 30 s, 640 × 480; 1.53 MB
  
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  A-Tubular-Biomaterial-Construct-Exhibiting-a-Negative-Poissons-Ratio-pone.0155681.s002.ogv 22 s, 640 × 480; 1.63 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s008.ogv 12 s, 1,488 × 832; 8.15 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s009.ogv 12 s, 1,488 × 832; 6.9 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s010.ogv 12 s, 1,488 × 832; 7.95 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s011.ogv 12 s, 1,488 × 832; 8.69 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s012.ogv 12 s, 1,488 × 832; 7.05 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s013.ogv 12 s, 1,488 × 832; 10.69 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s014.ogv 12 s, 1,488 × 832; 11.64 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s015.ogv 12 s, 1,488 × 832; 8.89 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s016.ogv 12 s, 1,488 × 832; 8.84 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s017.ogv 12 s, 1,920 × 1,004; 9.7 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s018.ogv 12 s, 1,920 × 1,004; 9.71 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s019.ogv 12 s, 1,920 × 1,004; 9.17 MB
  
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  A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s020.ogv 12 s, 1,920 × 1,004; 9.2 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s001.ogv 17 s, 1,200 × 800; 2.51 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s002.ogv 21 s, 1,200 × 800; 1.71 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s003.ogv 21 s, 1,200 × 800; 1.38 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s004.ogv 21 s, 1,200 × 800; 2.33 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s005.ogv 21 s, 1,200 × 800; 1.75 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s006.ogv 17 s, 1,200 × 800; 1.6 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s007.ogv 17 s, 1,200 × 800; 1.29 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s008.ogv 21 s, 1,200 × 800; 1.08 MB
  
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  Advancing-Edge-Speeds-of-Epithelial-Monolayers-Depend-on-Their-Initial-Confining-Geometry-pone.0153471.s009.ogv 17 s, 1,200 × 800; 726 KB
  
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  Agent-Based-Modeling-of-Mitochondria-Links-Sub-Cellular-Dynamics-to-Cellular-Homeostasis-and-pone.0168198.s010.ogv 13 s, 765 × 765; 8.63 MB
  
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  Agent-Based-Modeling-of-Mitochondria-Links-Sub-Cellular-Dynamics-to-Cellular-Homeostasis-and-pone.0168198.s011.ogv 13 s, 765 × 765; 8.05 MB
  
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  Agent-Based-Modeling-of-Mitochondria-Links-Sub-Cellular-Dynamics-to-Cellular-Homeostasis-and-pone.0168198.s012.ogv 12 s, 765 × 765; 7.13 MB
  
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  Agent-Based-Modeling-of-Mitochondria-Links-Sub-Cellular-Dynamics-to-Cellular-Homeostasis-and-pone.0168198.s013.ogv 15 s, 765 × 765; 2.14 MB
  
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  Agent-Based-Modeling-of-Mitochondria-Links-Sub-Cellular-Dynamics-to-Cellular-Homeostasis-and-pone.0168198.s014.ogv 9.1 s, 765 × 765; 845 KB
  
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  Agent-Based-Modeling-of-Mitochondria-Links-Sub-Cellular-Dynamics-to-Cellular-Homeostasis-and-pone.0168198.s015.ogv 10 s, 765 × 765; 9.11 MB
  
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  Agent-Based-Modeling-of-Mitochondria-Links-Sub-Cellular-Dynamics-to-Cellular-Homeostasis-and-pone.0168198.s016.ogv 10 s, 765 × 765; 9.26 MB
  
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  Automated-Design-of-Complex-Dynamic-Systems-pone.0086696.s001.ogv 6.0 s, 458 × 422; 828 KB
  
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  Automated-Design-of-Complex-Dynamic-Systems-pone.0086696.s004.ogv 6.7 s, 404 × 370; 1.17 MB
  
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  Biomechanics-of-the-Peacocks-Display-How-Feather-Structure-and-Resonance-Influence-Multimodal-pone.0152759.s002.ogv 1 min 13 s, 640 × 480; 26.79 MB
  
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  Biomechanics-of-the-Peacocks-Display-How-Feather-Structure-and-Resonance-Influence-Multimodal-pone.0152759.s003.ogv 12 s, 640 × 480; 2.46 MB
  
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  Biomechanics-of-the-Peacocks-Display-How-Feather-Structure-and-Resonance-Influence-Multimodal-pone.0152759.s004.ogv 27 s, 640 × 480; 12.35 MB
  
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  Biomechanics-of-the-Peacocks-Display-How-Feather-Structure-and-Resonance-Influence-Multimodal-pone.0152759.s005.ogv 21 s, 640 × 480; 3.12 MB
  
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  Bowstring-Stretching-and-Quantitative-Imaging-of-Single-Collagen-Fibrils-via-Atomic-Force-Microscopy-pone.0161951.s001.ogv 54 s, 945 × 702; 2.84 MB
  
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  Causal-Inference-in-Multisensory-Heading-Estimation-pone.0169676.s006.ogv 43 s, 540 × 960; 15.77 MB
  
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  Cervical-Spine-Injuries-A-Whole-Body-Musculoskeletal-Model-for-the-Analysis-of-Spinal-Loading-pone.0169329.s002.ogv 18 s, 1,024 × 768; 3.96 MB
  
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  Collective-Signal-Processing-in-Cluster-Chemotaxis-Roles-of-Adaptation-Amplification-and-Co-pcbi.1005008.s001.ogv 1 min 3 s, 640 × 480; 12.89 MB
  
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  Collective-Signal-Processing-in-Cluster-Chemotaxis-Roles-of-Adaptation-Amplification-and-Co-pcbi.1005008.s002.ogv 1 min 3 s, 928 × 306; 11.29 MB
  
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  Concentration-Sensing-by-the-Moving-Nucleus-in-Cell-Fate-Determination-A-Computational-Analysis-pone.0149213.s005.ogv 50 s, 1,127 × 334; 1.07 MB
  
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  Coordination-of-Cellular-Dynamics-Contributes-to-Tooth-Epithelium-Deformations-pone.0161336.s009.ogv 45 s, 960 × 720; 7.02 MB
  
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  Coordination-of-Cellular-Dynamics-Contributes-to-Tooth-Epithelium-Deformations-pone.0161336.s013.ogv 30 s, 715 × 720; 12.23 MB
  
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  Deformability-Assessment-of-Waterborne-Protozoa-Using-a-Microfluidic-Enabled-Force-Microscopy-Probe-pone.0150438.s006.ogv 12 s, 704 × 544; 44 KB
  
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  Density-Gradient-Mediated-Band-Extraction-of-Leukocytes-from-Whole-Blood-Using-Centrifugo-Pneumatic-pone.0155545.s001.ogv 2 min 43 s, 1,280 × 720; 17.39 MB
  
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  Doing-It-Your-Way-How-Individual-Movement-Styles-Affect-Action-Prediction-pone.0165297.s004.ogv 1.0 s, 1,280 × 800; 251 KB
  
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  Dynamic-Modelling-of-Tooth-Deformation-Using-Occlusal-Kinematics-and-Finite-Element-Analysis-pone.0152663.s008.ogv 34 s, 1,920 × 1,080; 1.72 MB
  
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  Dynamic-Modelling-of-Tooth-Deformation-Using-Occlusal-Kinematics-and-Finite-Element-Analysis-pone.0152663.s009.ogv 8.2 s, 1,920 × 1,080; 1.32 MB
  
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  Dynamic-Modelling-of-Tooth-Deformation-Using-Occlusal-Kinematics-and-Finite-Element-Analysis-pone.0152663.s010.ogv 8.2 s, 1,920 × 1,080; 3.5 MB
  
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  Evidence-for-Ventilation-through-Collective-Respiratory-Movements-in-Giant-Honeybee-(Apis-dorsata)-pone.0157882.s004.ogv 1 min 18 s, 1,024 × 576; 7.68 MB
  
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  Evidence-for-Ventilation-through-Collective-Respiratory-Movements-in-Giant-Honeybee-(Apis-dorsata)-pone.0157882.s005.ogv 24 s, 720 × 576; 5.68 MB
  
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  Fast-online-deconvolution-of-calcium-imaging-data-pcbi.1005423.s002.ogv 22 s, 800 × 400; 314 KB
  
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  Fast-online-deconvolution-of-calcium-imaging-data-pcbi.1005423.s003.ogv 1 min 8 s, 1,080 × 432; 1.9 MB
  
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  Feeding-Behavior-of-Subadult-Sixgill-Sharks-(Hexanchus-griseus)-at-a-Bait-Station-pone.0156730.s002.ogv 1 min 58 s, 720 × 480; 25.44 MB
  
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  Feeding-Behavior-of-Subadult-Sixgill-Sharks-(Hexanchus-griseus)-at-a-Bait-Station-pone.0156730.s003.ogv 33 s, 720 × 480; 13.07 MB
  
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  Feeding-Behavior-of-Subadult-Sixgill-Sharks-(Hexanchus-griseus)-at-a-Bait-Station-pone.0156730.s004.ogv 50 s, 641 × 484; 21.87 MB
  
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  Feeding-Behavior-of-Subadult-Sixgill-Sharks-(Hexanchus-griseus)-at-a-Bait-Station-pone.0156730.s005.ogv 1 min 0 s, 641 × 484; 21.57 MB
  
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  Feeding-Behavior-of-Subadult-Sixgill-Sharks-(Hexanchus-griseus)-at-a-Bait-Station-pone.0156730.s006.ogv 19 s, 720 × 480; 1.5 MB
  
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  First-Person-Perspective-Virtual-Body-Posture-Influences-Stress-A-Virtual-Reality-Body-Ownership-pone.0148060.s003.ogv 1 min 38 s, 854 × 480; 22.69 MB
  
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  FISICO-Fast-Image-SegmentatIon-COrrection-pone.0156035.s001.ogv 1 min 47 s, 712 × 480; 12.91 MB
  
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  Flapping-before-Flight-High-Resolution-Three-Dimensional-SkeletalKinematics-of-Wings-and-Legs-pone.0153446.s002.ogv 39 s, 480 × 480; 1.26 MB
  
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  Flapping-before-Flight-High-Resolution-Three-Dimensional-SkeletalKinematics-of-Wings-and-Legs-pone.0153446.s003.ogv 18 s, 360 × 480; 556 KB
  
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  Flapping-before-Flight-High-Resolution-Three-Dimensional-SkeletalKinematics-of-Wings-and-Legs-pone.0153446.s005.ogv 4.2 s, 1,180 × 884; 1.54 MB
  
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  Flapping-before-Flight-High-Resolution-Three-Dimensional-SkeletalKinematics-of-Wings-and-Legs-pone.0153446.s006.ogv 0.7 s, 1,024 × 1,024; 337 KB
  
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  Fluctuating-Nonlinear-Spring-Model-of-Mechanical-Deformation-of-Biological-Particles-pcbi.1004729.s011.ogv 27 s, 1,281 × 992; 26.85 MB
  
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  Forelimb-Kinematics-of-Rats-Using-XROMM-with-Implications-for-Small-Eutherians-and-Their-Fossil-pone.0149377.s010.ogv 1 min 47 s, 1,280 × 720; 32.74 MB
  
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  Forelimb-Kinematics-of-Rats-Using-XROMM-with-Implications-for-Small-Eutherians-and-Their-Fossil-pone.0149377.s011.ogv 17 s, 1,280 × 720; 3.05 MB
  
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  Forelimb-Kinematics-of-Rats-Using-XROMM-with-Implications-for-Small-Eutherians-and-Their-Fossil-pone.0149377.s012.ogv 17 s, 1,280 × 720; 1.01 MB
  
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  Functional-and-Gait-Assessment-in-Children-and-Adolescents-Affected-by-Friedreichs-Ataxia-A-One-pone.0162463.s001.ogv 8.0 s, 640 × 480; 2.99 MB
  
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  Functional-Investigation-of-a-Non-coding-Variant-Associated-with-Adolescent-Idiopathic-Scoliosis-in-pgen.1005802.s015.ogv 5.1 s, 290 × 229; 368 KB
  
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  Functional-Investigation-of-a-Non-coding-Variant-Associated-with-Adolescent-Idiopathic-Scoliosis-in-pgen.1005802.s016.ogv 5.1 s, 608 × 311; 323 KB
  
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  Generation-of-the-Human-Biped-Stance-by-a-Neural-Controller-Able-to-Compensate-Neurological-Time-pone.0163212.s001.ogv 21 s, 1,128 × 834; 971 KB
  
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  Global-Neuromagnetic-Cortical-Fields-Have-Non-Zero-Velocity-pone.0148413.s003.ogv 9.4 s, 640 × 400; 803 KB
  
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  Honeycomb-Actuators-Inspired-by-the-Unfolding-of-Ice-Plant-Seed-Capsules-pone.0163506.s001.ogv 6.1 s, 800 × 600; 7.99 MB
  
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  Honeycomb-Actuators-Inspired-by-the-Unfolding-of-Ice-Plant-Seed-Capsules-pone.0163506.s004.ogv 7.3 s, 4,672 × 3,104; 23.3 MB
  
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  Invagination-of-Ectodermal-Placodes-Is-Driven-by-Cell-Intercalation-Mediated-Contraction-of-the-pbio.1002405.s005.ogv 5.0 s, 1,450 × 526; 763 KB
  
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  Invagination-of-Ectodermal-Placodes-Is-Driven-by-Cell-Intercalation-Mediated-Contraction-of-the-pbio.1002405.s006.ogv 3.4 s, 1,178 × 450; 265 KB
  
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  Invagination-of-Ectodermal-Placodes-Is-Driven-by-Cell-Intercalation-Mediated-Contraction-of-the-pbio.1002405.s007.ogv 2.3 s, 1,042 × 256; 91 KB
  
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  Invagination-of-Ectodermal-Placodes-Is-Driven-by-Cell-Intercalation-Mediated-Contraction-of-the-pbio.1002405.s008.ogv 3.4 s, 1,751 × 573; 1.3 MB
  
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  Invagination-of-Ectodermal-Placodes-Is-Driven-by-Cell-Intercalation-Mediated-Contraction-of-the-pbio.1002405.s009.ogv 3.9 s, 1,290 × 1,690; 4.26 MB
  
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  Invagination-of-Ectodermal-Placodes-Is-Driven-by-Cell-Intercalation-Mediated-Contraction-of-the-pbio.1002405.s010.ogv 4.2 s, 618 × 167; 280 KB
  
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  Invagination-of-Ectodermal-Placodes-Is-Driven-by-Cell-Intercalation-Mediated-Contraction-of-the-pbio.1002405.s011.ogv 14 s, 732 × 563; 1.3 MB
  
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  Klassieke Mechanica.pdf 1,240 × 1,753, 283 pages; 4.35 MB
  
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  Long-term-trends-in-the-honeybee-whooping-signal-revealed-by-automated-detection-pone.0171162.s017.ogv 4 min 5 s, 1,920 × 1,080; 31.56 MB
  
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  Long-term-trends-in-the-honeybee-whooping-signal-revealed-by-automated-detection-pone.0171162.s018.ogv 13 s, 1,920 × 1,080; 47.87 MB
  
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